A semiconductor integrated circuit is provided comprising a first amplifier circuit which receives a first potential and then supplies a current to an output terminal; a second amplifier circuit which receives a second potential and then absorbs a current from the output terminal; and a control circuit which controls the second amplifier circuit so as to allow the second amplifier circuit to be activated subsequently to a predetermined period of time that elapses after the first amplifier circuit is activated.
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1. A semiconductor integrated circuit, comprising:
a first amplifier circuit which receives a first potential and then supplies a current to an output terminal;
a second amplifier circuit which receives a second potential and then absorbs a current from the output terminal; and
a control circuit which controls the second amplifier circuit so that the second amplifier circuit starts operating subsequent to a predetermined period of time that elapses after the first amplifier is activated, wherein
the control circuit, by counting a clock signal, makes a state of a second control signal supplied to the second amplifier circuit change subsequent to a predetermined period of time that elapses after a state of a first control signal supplied to the first amplifier circuit changes.
2. The semiconductor integrated circuit according to
3. The semiconductor integrated circuit according to
the first amplifier circuit comprises a first differential amplifier and a p-channel transistor of an output stage; and
the second amplifier circuit comprises a second differential amplifier and an n-channel transistor of the output stage.
4. The semiconductor integrated circuit according to
the first amplifier circuit further comprises a first transistor which makes the p-channel transistor of the output stage cut off according to a first control signal in a first mode; and
the second amplifier circuit further comprises a first transistor which makes the n-channel transistor of the output stage cut off according to a second control signal in the first mode and a second mode.
5. The semiconductor integrated circuit according to
the first amplifier circuit further comprises a second transistor which supplies a current to two transistors forming a differential pair of the first differential amplifier according to a first control signal in the second mode and a third mode; and
the second amplifier circuit further comprises a second transistor which supplies a current to two transistors forming a differential pair of the second differential amplifier according to a second control signal in the third mode.
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1. Field of the Invention
The present invention relates to a semiconductor integrated circuit such as an LCD driver including a voltage-follower power circuit which supplies a given voltage to a load in a push-pull manner.
2. Description of the Related Art
Some power circuits for conventional LCD drivers employ a push-pull method as shown in FIG. 5. The power circuit shown in
A first potential V10 and a second potential V20, which are obtained by dividing a given potential VL of the low-voltage side and a given potential VH of the high-voltage side by resistors R10, R20, and R30, are applied to the amplifier circuits 100 and 200, respectively. Since the lower first potential V10 is applied to the first amplifier circuit 100 and the higher second potential V20 is applied to the second amplifier circuit 200, the p-channel transistor of the output stage of the first amplifier circuit 100 and the n-channel transistor of the output stage of the second amplifier circuit 200 generally do not operate simultaneously.
However, when the power circuit is activated, the potential at each component is unstable. Consequently, the p-channel transistor of the output stage of the first amplifier circuit 100 and the n-channel transistor of the output stage of the second amplifier circuit 200 may operate simultaneously, which can undesirably cause a large current. Moreover, another problem is that an output voltage of the power circuit oscillates as if to ripple when increasing an offset of the first potential V10 and the second potential V20 by increasing the value of the resistor R20.
Japanese Unexamined Patent Application Publication No. 61-79312 describes a DC amplifier comprising an offset adjustment means which inputs DC elements included in the output of an amplifier to a window comparator, successively sends a control signal to a multiplexer by operating a comparison resistor upon exceeding a certain level, and controls the midpoint of the common source resistor of a first stage amplifier.
Japanese Unexamined Patent Application Publication No. 7-106875 describes a semiconductor integrated circuit comprising differential transistors, a transistor for current source connected to source electrodes connected to each other in the differential transistors, a resistor and a current source transistor for current source connected in parallel to the above-mentioned transistors, and a comparator which compares voltages of both ends of the resistor with a reference voltage and brings its output to the two transistors for current source.
However, the technologies described in these applications are not for controlling push-pull operations of the output stage, but for adjusting DC offsets of output potentials.
Taking the above-mentioned facts into consideration, an object of the present invention is to prevent a large current flowing from a p-channel transistor to an n-channel transistor of the output stage when a power circuit is activated in a semiconductor integrated circuit comprising the power circuit which supplies a given voltage to a load in a push-pull manner.
To achieve the above-mentioned object, the semiconductor integrated circuit according to the present invention comprises a first amplifier circuit which receives a first potential and then supplies a current to an output terminal; a second amplifier circuit which receives a second potential and then absorbs a current from the output terminal; and a control circuit which controls the second amplifier circuit so as to allow the second amplifier circuit to be activated subsequently to a predetermined period of time that elapses after the first amplifier circuit is activated.
The semiconductor integrated circuit may further comprise a potential generating circuit, which generates a first potential and a second potential so as to make the first potential higher than the second potential.
In such a semiconductor integrated circuit, the first amplifier circuit may comprise a first differential amplifier and a p-channel transistor of the output stage, and the second amplifier circuit may comprise a second differential amplifier and an n-channel transistor of the output stage.
In this case, the first amplifier circuit may comprise a transistor which makes the p-channel transistor of the output stage cut off according to a first control signal in a first mode, and the second amplifier circuit may comprise a transistor which makes the n-channel transistor of the output stage cut off according to a second control signal in the first and a second mode.
Furthermore, the first amplifier circuit may comprise a transistor which supplies a current to two transistors forming a differential pair of the first differential amplifier according to a first control signal in the second mode and a third mode, and the second amplifier circuit may comprise a transistor which supplies a current to two transistors forming a differential pair of the second differential amplifier according to a second control signal in the third mode.
In the above-mentioned case, the control circuit may, by counting a clock signal, make the state of a second control signal supplied to the second amplifier circuit change subsequently to a predetermined period of time that elapses after the state of a first control signal supplied to the first amplifier circuit changes.
According to the present invention comprised as mentioned, in the semiconductor integrated circuit comprising a power circuit, which supplies a given voltage to a load in a push-pull manner, a large current flowing from a p-channel transistor to an n-channel transistor of the output stage when the power circuit is activated can be prevented. This is achieved by allowing the second amplifier circuit, which allows a current to be absorbed into the n-channel transistor from an output terminal, to be activated subsequently to a predetermined period of time that elapses after the first amplifier circuit is activated, which supplies a current from the p-channel transistor to the output terminal.
An embodiment of the present invention is described below based on the drawings.
A first potential V1 and a second potential V2, which are obtained by dividing a given potential VL of a low-voltage side and a given potential VH of a high-voltage side by resistors R1, R2, and R3, are applied to the amplifier circuits 10 and 20, respectively. The lower first potential V1 is applied to the first amplifier circuit 10, while the higher second potential V2 is applied to the second amplifier circuit 20. When the power circuit is activated, the p-channel transistor of the output stage of the first amplifier circuit 10 and the n-channel transistor of the output stage of the second amplifier circuit 20 may operate simultaneously because the potential at each component is unstable. However, activating the second amplifier circuit 20 subsequently to a predetermined period of time that elapses after the first amplifier circuit 10 is activated, can prevent a large current flowing in the amplifier circuits 10 and 20.
The first amplifier circuit 10 comprises a differential amplifier comprising p-channel transistors QP1 and QP2, and n-channel transistors QN3 and QN4; an n-channel transistor QN5, which turns on and off an operating current of the differential amplifier; a p-channel transistor QP6 of the output stage; a p-channel transistor QP7, which cuts off the transistors of the output stage; and a capacitor C1 for phase compensation.
When the first control signal PS1 bar remains at a low level, the transistor QN5 is “off” and thereby the differential amplifier is suspended, while the transistor QP7 is “on” and thereby the transistor QP6 of the output stage is cut off. On the contrary, when the first control signal PS1 bar is turned to a high level, the transistor QN5 is switched on and thereby the differential amplifier is activated, while the transistor QP7 is switched off and thereby the transistor QP6 of the output stage is activated.
The second amplifier circuit 20 comprises a differential amplifier comprising n-channel transistors QN1 and QN2, and p-channel transistors QP3 and QP4; a p-channel transistor QP5, which turns on and off an operating current of the differential amplifier; an n-channel transistor QN6 of the output stage; an n-channel transistor QN7, which cuts off the transistors of the output stage; and a capacitor C2 for phase compensation.
When the second control signal PS2 remains at a high level, the transistor QP5 is “off” and thereby the differential amplifier is suspended, while the transistor QN7 is “on” and thereby the transistor QN6 of the output stage is cut off. On the contrary, when the second control signal PS2 is turned to a low level, the transistor QP5 is switched on and thereby the differential amplifier is activated, while the transistor QN7 is switched off and thereby the transistor QN6 of the output stage is activated.
Referring to
When the power save mode is thus cleared, by shifting a time for activating the amplifier circuit 10 from a time for activating the amplifier circuit 20,a short-circuit current from the transistor QP6 of the output stage of the first amplifier circuit 10 to the transistor QN6 of the output stage of the second amplifier circuit 20 can be prevented thereby. In particular, when a potential of the output terminal rises, a high potential is applied to a gate of the transistor QN6 of the output stage of the second amplifier circuit 20 via the capacitor C2 for phase compensation. However, making the transistor QN7 remain “on” for a predetermined period of time can prevent an excessive current flowing in the transistor QN6 of the output stage. Furthermore, since it is unnecessary to increase an offset between the first potential V1 and the second potential V2, the problem that an output voltage of the power circuit oscillates as if to ripple can be solved.
As described herein, according to the present invention, in a semiconductor integrated circuit comprising a power circuit, which supplies a given voltage to a load in a push-pull manner, a large current flowing from a p-channel transistor to an n-channel transistor of the output stage when the power circuit is activated can be prevented.
The entire disclosure of Japanese Patent Application No. 2002-272471 filed Sep. 19, 2002 is incorporated by reference.
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